Temperature Measuring Method Accuracy Evaluation in the Microarc Heating Process Based on Reproducibility and Uncertainty Indicators

IF 0.2 Q4 INSTRUMENTS & INSTRUMENTATION
M. S. Stepanov, I. G. Koshlyakova
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Abstract

It is necessary to control temperature using thermoelectric sensors for steel products surface alloying in conditions of microarc heating. The using S-type thermocouples possibility has been substantiated, main factors affecting the measurement results have been established, and the the reproducibility index functional dependence on the measured temperature has been determined, as a result of previous studies. However, additional influencing factors that may affect to the heating process kinetics and the temperature measurements results were not taken into account. The purpose of the work was a steel temperature measurement results uncertainty generalized assessment during microarc heating, taking into account most complete influencing factors set. Influencing factors comprise: average coal powder particle size (X1), sample diameter (X2); chromium content in steel (X3 ). The measurement error was denoted Y. The dependence is obtained: Y = –4.032X1 – 0.095X2 + 0.0058X3 + 3.414. Thus, in the studied range of values, an increase in the powder particle and the samples diameter size leads to a decrease in the measurement error, and the chromium content increase leads to its increase. Therefore, the temperature measurement error during microarc heating can be reduced with decrease the sample heating rate, as well as with increase the heat transfer intensity from its surface to the material depth due to an increase the size, and, accordingly, the processed products mass. Next, the studied factors values distribution laws were evaluated. For X1 and X2, the normal distribution law is adopted, for X3 – uniform. Taking into account each factor's influence coefficients, and the total uncertainty estimate introduced assessment by them, a generalized uncertainty estimate was found: U = 1.1 °C. The microarc heating temperature measurement method quantitative assessment detailed of the accuracy makes it possible to take into account all significant influencing factors and their total measurement uncertainty contribution. The obtained temperature measurement's total uncertainty value from the three studied factors can be used as a priori information as a type B uncertainty during the microarc saturation process.
基于可重复性和不确定性指标的微弧加热过程温度测量方法精度评估
在微弧加热条件下进行钢铁产品表面合金化时,有必要使用热电传感器控制温度。之前的研究已经证实了使用 S 型热电偶的可能性,确定了影响测量结果的主要因素,并确定了重现性指数与测量温度的函数关系。然而,可能影响加热过程动力学和温度测量结果的其他影响因素并未考虑在内。这项工作的目的是对微弧加热过程中钢材温度测量结果的不确定性进行综合评估,同时考虑到最完整的影响因素集。影响因素包括:煤粉平均粒度 (X1)、试样直径 (X2)、钢中铬含量 (X3)。测量误差用 Y 表示:Y = -4.032x1 - 0.095x2 + 0.0058x3 + 3.414。因此,在所研究的数值范围内,粉末颗粒和样品直径尺寸的增加会导致测量误差的减小,而铬含量的增加会导致测量误差的增大。因此,微弧加热过程中的温度测量误差可以随着样品加热速率的降低而减小,也可以随着从表面到材料深度的热传导强度的增加而减小,这是因为尺寸增大,加工产品的质量也相应增大。接下来,对所研究的因子值分布规律进行了评估。X1 和 X2 采用正态分布规律,X3 采用均匀分布规律。考虑到每个因素的影响系数,以及由它们引入评估的总不确定度估计值,得出了一个通用的不确定度估计值:U = 1.1 °C。微弧加热温度测量方法的精确度定量评估详尽地考虑了所有重要的影响因素及其总测量不确定度。在微弧饱和过程中,从三个研究因素中获得的温度测量总不确定度值可作为 B 类不确定度的先验信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Devices and Methods of Measurements
Devices and Methods of Measurements INSTRUMENTS & INSTRUMENTATION-
自引率
25.00%
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审稿时长
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